Retry disparity for control channel of a multimedia communication link

ABSTRACT

A multimedia system for data communications. A source device communicates data over a full duplex control channel of a multimedia communication link. The source device has a first link layer that retries unsuccessful data communications over the full duplex control channel until a first maximum retry limit of the first link layer is reached. A sink device communicates data over the full duplex control channel of the multimedia communication link. The sink device has a second link layer that retries unsuccessful data communications over the full duplex control channel until a second maximum retry limit of the second link layer is reached, where the second maximum retry limit is different than the first maximum retry limit.

BACKGROUND

1. Field of the Disclosure

This disclosure pertains in general to a multimedia system, and morespecifically to controlling communications over a control channel of amultimedia communication link.

2. Description of the Related Art

Devices that communicate over a control channel of a multimediacommunication link (e.g., Mobile High Definition Link (MHL)) havetraditionally been half duplex at both the translation layer and linklayer. Changing the link layer to full duplex can increase the bandwidthacross the control channel. However, a full duplex link layer may not bebackwards compatible with existing half duplex translation layers unlesscomplex conflict resolution logic is added to the full duplex linklayer.

SUMMARY

Embodiments of the present disclosure are related to systems and devicesfor communication over a control channel of a multimedia communicationlinks. In one embodiment, a system for data communications is disclosed.The system comprises a multimedia communication link having a fullduplex control channel. A source device communicates over the fullduplex control channel of the multimedia communication link using timedomain multiplexed (TDM) frames having n time slots per frame. Thesource device allocates a first time slot position to a virtual channelfor data transmission by the source device over the full duplex controlchannel. A sink device communicates over the full duplex control channelof the multimedia communication link. The sink device allocates a secondtime slot position to the virtual channel for data transmission by thesink device over the full duplex control channel. A timing of the secondtime slot position is offset from a timing of the first time slotposition by substantially n/2 time slots.

In another embodiment, a first device for data communications with asecond device via a multimedia communication link is disclosed. Thefirst device includes an interface for coupling to a full duplex controlchannel of the multimedia communications link. The first device alsoincludes a link layer to communicate over the full duplex controlchannel using time domain multiplexed (TDM) frames having n time slotsper frame. The link layer allocates a first time slot position to avirtual channel for data transmission by the first device over the fullduplex control channel. A second time slot position is allocated to thevirtual channel for data transmission from the second device over thefull duplex control channel. A timing of the second time slot positionis offset from a timing of the first time slot position by substantiallyn/2 time slots.

In a further embodiment, a system for data communications includes amultimedia communication link having a full duplex control channel. Asource device communicates data over the full duplex control channel ofthe multimedia communication link. The source device has a first linklayer that retries unsuccessful data communications over the full duplexcontrol channel until a first maximum retry limit of the first linklayer is reached. A sink device communicates data over the full duplexcontrol channel of the multimedia communication link. The sink devicehas a second link layer that retries unsuccessful data communicationsover the full duplex control channel until a second maximum retry limitof the second link layer is reached, where the second maximum retrylimit is different than the first maximum retry limit.

In yet another embodiment, a first device for data communications with asecond device via a multimedia communication link is disclosed. Thefirst device comprises an interface to a full duplex control channel ofthe multimedia communication link. A link layer communicates data withthe second device over the full duplex control channel. The link layerretries unsuccessful data communications over the full duplex controlchannel until a first maximum retry limit is reached. The first maximumretry limit is different than a second maximum retry limit of a linklayer of the second device.

BRIEF DESCRIPTION OF THE DRAWINGS

The teachings of the embodiments disclosed herein can be readilyunderstood by considering the following detailed description inconjunction with the accompanying drawings.

FIG. 1 is a high-level block diagram of a multimedia system formultimedia data communication using time division multiplexing,according to one embodiment.

FIG. 2 is a diagram illustrating virtual channels set to offset timeslots in the multimedia system of FIG. 1, according to an embodiment.

FIG. 3 is a flowchart of a method for setting offset time slots for avirtual channel in the multimedia system of FIG. 1, according to anembodiment.

FIG. 4 is a diagram illustrating acknowledgement timing, according to anembodiment.

FIG. 5 is a high-level block diagram of a multimedia system formultimedia data communication with retry disparity, according to anotherembodiment.

FIG. 6 is a diagram illustrating the problem faced by the multimediasystem of FIG. 5, according to an embodiment.

FIG. 7 is a diagram illustrating retry disparity in the multimediasystem of FIG. 5, according to an embodiment.

DETAILED DESCRIPTION

The Figures (FIG.) and the following description relate to variousembodiments by way of illustration only. It should be noted that fromthe following discussion, alternative embodiments of the structures andmethods disclosed herein will be readily recognized as viablealternatives that may be employed without departing from the principlesdiscussed herein. Reference will now be made in detail to severalembodiments, examples of which are illustrated in the accompanyingfigures. It is noted that wherever practicable similar or like referencenumbers may be used in the figures and may indicate similar or likefunctionality.

Embodiment of the present disclosure relate to systems for communicationover a full duplex control channel of a multimedia communication linkwhile retaining a half duplex translation layer. For example, themultimedia communication link may be MHL that has a full duplex enhancedcontrol bus (eCBUS). A source device and sink device set the timing ofTDM time slot positions for a virtual channel such the TDM time slotposition in one direction (e.g. from source to sink) is offset from theTDM time slot position in the other direction (e.g. from sink to source)by substantially half a TDM frame. Offsetting TDM time slots indifferent directions reduces the need for complex conflict handlinglogic at the link layers of the source device and sink device.Additionally, the source device and sink device may have asymmetricmaximum retry limits at the link layers, which prevents communicationdeadlocks.

Offset Phase Relationship of Time Slots

FIG. 1 is a high-level block diagram of a multimedia system 100 formultimedia data communications, according to one embodiment. Themultimedia system 100 includes a source device 110 communicating with asink device 115 through a multimedia communication link 150. Sourcedevices 110 are sources of video data streams. Examples of source device110 can be mobile phones, digital video disc (DVD) players, blu-rayplayers, cable boxes, internet protocol television (IPTV) boxes,laptops, or integrated circuits (IC) within such devices. Sink devices115 receive video data streams, and may include functionality to displaythe video data streams. Examples of sink devices 115 include liquidcrystal display (LCD) televisions, LCD monitors, or ICs within suchdevices.

The multimedia communication link 150 includes a physical multimediachannel 152 and a physical control channel 156. Source device 110 iscoupled to the multimedia channel 152 and control channel 156 throughinterface 153. Sink device 115 is coupled to the multimedia channel 152and the control channel 156 through interface 157. Interfaces 153, 157are physical elements through which communications can occur. Examplesof interfaces 153, 157 are connectors, pins, driving circuits, orreceiving circuits, among others.

The source device 110 transmits multimedia (e.g., video/audio/auxiliary)data streams to the sink device 115 across the multimedia channel 152.The multimedia channel 152 is one-directional and carries multimediadata streams from the source device 110 to the sink device 115. Themultimedia channel 152 may be implemented using a differential pair ofwires. In other embodiments there may be multiple multimedia channels152 for transferring one or more video data streams. The video datastream can be displayed at the sink device 115 or passed on to anotherdevice for display.

The source device 110 and sink device 115 also exchange control dataacross the control channel 156. The control channel 156 isbi-directional and full duplex such that the source device 110 and sinkdevice 115 can transfer control data with each other at the same time.Control data can include control commands, remote control data, copyprotection information, extended display identification data (EDID),tunneled data, etc. The control channel 156 may be implemented using adifferential pair of wires or a single pair of wires.

In one embodiment, the multimedia communication link 150 is a mobilehigh definition link (MHL) and the control channel 156 is an enhancedcontrol bus (eCBUS) for MHL. However, embodiments of the presentdisclosure are not restricted to MHL and can include embodiments wherethe multimedia communication link 150 is a high definition multimediainterface (HDMI) link or other type of multimedia communication link.

The source device 110 includes a source translation layer 120 and asource link layer 130. The translation layer 130 includes circuitry thatsupports several different source communication protocols 122 a-122 z.Each protocol 122 specifies a different set of rules for communicationof a different type of control data. Examples of protocols 122 includeprotocols for MHL sideband channel (MSC) and display data channel (DDC),among others. The protocols 122 operate in half-duplex, meaning thatthey can be either in a transmit state or a receive state at any giventime, but cannot support both data transmission and data reception atthe same time.

The link layer 130 receives control data from the protocols 122,packetizes the control data, and uses time division multiplexing (TDM)to map the packets onto the control channel 156. The link layer 130treats each protocol 122 as a different virtual channel VCa-VCz. Eachvirtual channel is allocated to one or more time slot positions within aTDM frame for transmission across the control channel 156 throughinterface 153. The link layer 130 also receives TDM frames from thecontrol channel 156. The link layer 130 decodes the TDM frames toextract control data. The control data is then forwarded on to theappropriate protocol 122. The link layer 130 communicates in full-duplexwith the sink device 115 over the control channel 156 to both transmitand receive control data at the same time.

The sink device 115 includes a sink link layer 180 and a sinktranslation layer 190. The sink translation layer 190 includes severalsink communication protocols 192 a-192 z that communicate with thesource communication protocols 122 a-122 z through virtual channelsVCa-VCz. The source side of a protocol 122 and the sink side of aprotocol 192 are counterparts of the same overall communicationprotocol. For example, Protocol A includes both the source side ProtocolA 122 a and the sink side Protocol A 192 a, both of which communicatewith each other according a set of pre-defined protocol rules.

The sink link layer 180 and sink translation layer 190 are similar infunction to their counterparts in the source device 110. Thus, thedescription of the source translation layer 120 and source link layer130 herein generally apply to the sink link layer 180 and sinktranslation layer 190 as well.

There may be also differences between the source link layer 130 and sinklink layer 180. One difference is that the sink link layer 180 includesa TDM timing control block 181. TDM timing control block 181 ensuresthat TDM frames generated by link layer 130 have a half TDM frame phaseoffset from the TDM frames generated by link layer 180. As a result, fora given virtual channel, the time slot position(s) for the virtualchannel in one direction (e.g., from source 110 to sink 115) is offsetfrom the time slot position(s) in the other direction (e.g., from sink115 to source 110) by substantially half a TDM frame. Offsetting is nowexplained in greater detail by reference to FIG. 2.

FIG. 2 is a diagram illustrating virtual channels set to offset timeslot positions in the multimedia system 100 of FIG. 1, according to anembodiment. The link layers 130 and 180 divide the bandwidth of thecontrol channel 156 into repeating time slots using TDM. Communicationsacross the control channel 156 can be logically divided into source timeslots 202 and sink time slots 204. Source time slots 202 represent timeslots for transmission of control data from the source link layer 130 tothe sink link layer 180 across the control channel 156. Sink time slots204 represent time slots for transmission of control data from the sinklink layer 180 to the source link layer 130 across the control channel156. The control channel 156 is full duplex so the source time slots 202and sink time slots 204 are used to transfer data across the controlchannel 156 simultaneously in both directions. The time slots are alsoorganized into TDM frames, where each TDM frame includes n time slotpositions, from slot position 0 to slot position n−1.

The source link layer 130 allocates slot positions within the source TDMframes to virtual channels, where each virtual channel represents adifferent source communication protocol 122. The sink link layer 180also allocates slot positions within the sink TDM frames to the virtualchannels for communications in the reverse direction. For example,virtual channel VCa may be allocated to slot position 0 in both thesource time slots 202 and sink time slots 214. Virtual channel VCb (notshown) may be allocated to slot positions 1 and 2 in both the sourcetime slots 212 and sink time slots 214.

The timing of the source TDM frames is offset from the timing of thesink TDM frames by n/2 time slots. For a given virtual channel, thiscauses the source slot positions allocated to the virtual channel to beoffset from the sink slot positions allocated to the same virtualchannel. As shown in FIG. 2, virtual channel a (VCa) is allocated tosource slot position 0 212. VCa represents communication protocol A. VCais also allocated to sink slot position 0 214. The timing of source slotposition 0 212 is offset from the timing of sink slot position 0 214 byn/2 time slots. This means that sink slot position 0 214 is placedhalfway between adjacent source slot position 0's 212.

Offsetting source TDM frames and sink TDM frames decreases the overallcomplexity of the link layer 130 when the translation layer protocols122 are half duplex. Half duplex translation layer protocols 122 canonly be in a transmit or receive state at any given time. However, thesource side of a protocol 122 a and the sink side of the same protocol192 a may sometimes attempt to enter the transmit state and send controldata at the same time. If the source slot position and sink slotposition allocated to the protocol are too close together in time, thelink layers 130 and 180 will exchange conflicting or irrelevant controldata, and the link layers 130 and 180 will need logic to handle theseconflicts or manage the flow of data. This additional logic increasescomplexity and reduces bandwidth efficiency. However, by staggering thecommunications by n/2 time slots, both link layers 130 and 180 havesufficient time to process incoming control data and to suppressoutgoing control data that could cause conflicts or be irrelevant.

In one embodiment, source slot position 0 212 may be offset from sinkslot position 0 214 by substantially n/2 time slots as opposed toexactly n/2 time slots. The margin of error may be +/−10% of the totaltime slot positions in a TDM frame and still achieve the goal ofpreventing conflicts. For example, if there are 25 total time slotpositions in a TDM frame, source slot position 0 212 may be offset fromsink slot position 1 214 by 10-15 time slots. As another example, ifthere are 200 total time slot positions in a TDM frame, source slotposition 0 212 may be offset from sink slot position 1 214 by 80-120time slots.

FIG. 3 is a flowchart of a method for setting offset time slot positionsfor a virtual channel in the multimedia system 100 of FIG. 1, accordingto an embodiment. Data communications over the control channel 156typically involve a synchronization phase to set the timing of the timeslot positions, followed by a normal operational phase in which controldata can be transferred during the time slot positions. Duringsynchronization the source link layer 130 acts as the leader, and thesink link layer 180 acts as a follower that sets the timing of sink timeslot positions by reference to the timing of the source time slotpositions.

In step 305, the source link layer 305 sends a synchronization characterin source slot position 0 212 allocated to virtual channel a. Thesynchronization character is a pre-determined communication code that isused for synchronization purposes. The synchronization character isrepeatedly sent in the same source slot position 0 212 over multiplesource TDM frames. The sink link layer 180 receives the synchronizationcharacter in the source slot position 0 212.

In step 310, the sink link layer 180 identifies the synchronizationcharacter in the source time slots 202, and identifies the timing ofsource position slot 0 212 allocated to virtual channel a from thesynchronization character. In one embodiment, the sink link layer 180has an internal slot counter and forces the internal slot counter to n/2when the synchronization character is detected.

In step 315, the sink link layer 180 sets the timing of sink slotposition 0 by offsetting sink slot position 0 relative to source slotposition 0. The amount of the offset is a pre-determined offset of n/2time slots. The result is that sink TDM frames are offset from thesource TDM frames by n/2 time slots. In one embodiment, the previouslymentioned internal slot counter increments from n/2 to n−1, at whichpoint it resets to zero. When the count returns to zero, this phaseoffset is captured and used as the timing for sink slot position 0 214.

In step 317, the sink link layer 180 then sends a confirmation characterin sink slot position 0 to indicate that synchronization is successful.Steps 310 through 317 can be performed by the TDM timing block 181. Instep 318, the source link layer 180 then changes its synchronizationcharacter to a confirmation character in source slot position 0. Thiscompletes synchronization.

In step 320, the source link layer 130 and sink link layer 180 are nowsynchronized and begin exchanging control data across the controlchannel 156 during the slot positions 212 and 214 that are offset fromeach other in time. The offset slot positions prevent conflictingcontrol data for a protocol from being exchanged between the link layers130 and 180, as previously explained.

Referring back to FIG. 1, some of the source communication protocols 122may be older protocols having strict timing requirements forcommunications. One particular requirement is that once a protocol 122initiates a communication transaction, the protocol 122 expects thetransaction to be completed within a fixed amount of time (e.g. in 16us). The link layers 130 and 180 are designed to help meet thisrequirement so that the protocols 122 do not need to be re-designed foruse with a full duplex control channel 156, as will be explained in FIG.4.

FIG. 4 is a diagram illustrating acknowledgement timing in themultimedia system 100 of FIG. 1, according to an embodiment. FIG. 4 issimilar to FIG. 2, but now includes specific information sent duringsource time slots 401 a-c and sink time slot 404 c. Source protocol A122 a starts a communication by sending (not shown) 11 bits of controldata to the source link layer 130. The source link layer 130 packetizesthe control data into a 24 bit control data packet and sends the controlpacket during a source slot position 401 allocated to virtual channel 0over three consecutive TDM frames. The control data packet is sent asthree separate bytes: a packet preamble is sent during time slot 401 a,a high byte is sent during time slot 401 b, and a low byte is sentduring time slot 401 c. Once the entire packet is received by the sinklink layer 180, the sink link layer 180 responds with an acknowledgementACK or NACK in the next immediate sink time slot 404 c allocated tovirtual channel 0. The acknowledgement may then be forwarded (not shown)on to the source protocol A 122 a to complete the communicationtransaction.

Immediately acknowledging the control data packet in less than one TDMframe decreases the amount of time required to complete a communicationtransaction so that the requirements of the protocols 122 can be met.Additionally, sink slot position 401 is offset from source slot position404 by n/2 time slots. The worst case time for completing acommunication transaction is ˜3.5 TDM frames, which includes ˜1 TDMframe wait time for translation layer data that arrives early before itsallocated time slot, ˜2 TDM frames to transfer the control data packetin time slots 401 (i.e., 401 a-401 c), and ˜0.5 TDM frames for theacknowledgement in time slot 404 c. This worst case time is the sameregardless of whether the communication transaction is started by thesource translation layer 120 or sink translation layer 190, whichensures that communication transactions have substantially symmetricworst case times.

Retry Disparity

FIG. 5 is a high-level block diagram of a multimedia system 500 formultimedia data communication with retry disparity, according to anotherembodiment. The multimedia system 500 of FIG. 5 is similar to themultimedia system 100 of FIG. 1, but now the source link layer 130includes a maximum source retry limit 502, and the sink link layer 180includes a maximum sink retry limit 115. The maximum source retry limit502 limits the number of times the source link layer 130 will attempt toretry an unsuccessful communication over the control channel 156. Themaximum sink retry limit 504 limits the number of times the sink linklayer 180 will attempt to retry an unsuccessful communication over thecontrol channel 156.

The maximum sink retry limit 502 and maximum source retry limit 504 havedifferent values, which prevents deadlocks. Maximum sink retry limit 502may be greater than or less than maximum source retry limit 504. In oneembodiment, the maximum source retry limit 502 may be 4*X+3, where X isan integer. The maximum sink retry limit 504 may be 4*Y+1, wherein Y isan integer. X and Y may be the same or different values. For example, ifX and Y are both 1, the maximum source retry limit 502 is 7, and themaximum sink retry limit 504 is 5. X and Y may be selected at random, behardcoded, or negotiated by the source device 110 and sink device 115.

FIG. 6 is a diagram illustrating the problem faced by the multimediasystem 500 of FIG. 5, according to an embodiment. FIG. 6 showscommunications between source protocol A 122 a, source link layer 130,sink link layer 180, and sink protocol A 192 a. The communicationsbetween source link layer 130 and sink layer 180 in FIG. 6 may occurthrough a virtual channel (e.g., VCa).

A problem with data communications can occur when two sides of aprotocol attempt to enter the transmit state around the same time. Asshown in FIG. 6, initially source protocol A 122 a enters the transmitstate and transmits source control data 602 to the source link layer130. Around the same time, sink protocol A 192 a also enters thetransmit state and transmits sink control data 604 to the sink linklayer 180.

The source link layer 612 transmits source data 612 to the sink layer180 in response to receiving source data 602. Sink link layer 180 cannotpass the source data 612 onto sink protocol A 192 because sink protocolA, which is half duplex, is in the transmit state. Thus, sink link layer180 responds with a negative acknowledgement NACK 614 to the source linklayer 130 to indicate an unsuccessful communication.

Similarly, the sink link layer 180 also transmits sink data 616 to thesource link layer 130 in response to receiving sink data 604. However,source link layer 130 cannot pass the sink data 616 onto source protocolA 122 a because source protocol A 122 a, which is half duplex, is in thetransmit state. Thus, source link layer 130 responds with a NACK 618 tothe sink link layer 180 to indicate an unsuccessful communication.

The source link layer 130 attempts to retry the source datacommunication two times (620, 622). However, each repeated retry attemptalso fails. After two retries, the source link layer 130 sends a NACK624 to the source protocol A 122 a that causes the source protocol A 122a to exit the transmit state.

Similarly, the sink link layer 180 also attempts to retry the sink datacommunication two times (630, 632). However, each repeated retry attemptalso fails. After two retries, the sink link layer 180 sends a NACK 634to the sink protocol A 192 a that causes the sink protocol A 192 a toexit the transmit state.

In FIG. 6, the source link layer 130 and sink link layer 180 each retrya failed communication two times. This causes a deadlock where neitherside can successfully complete a communication transaction. Thisdeadlock problem in FIG. 6 is addressed by having different maximumretry limits for the source link layer 130 and sink link layer 180, aswill be explained by reference to FIG. 7.

FIG. 7 is a diagram illustrating retry disparity in the multimediasystem 500 of FIG. 5, according to an embodiment. In FIG. 7, the sourcelink layer 130 retries failed communications over the control channel156 two times (620, 622). The sink link layer 180 retries failedcommunications over the control channel 156 three times (630, 632, 702).The last retry 702 by the sink link layer 180 is successful because thesource protocol A 122 a is no longer in the transmit state, which allowssink data to be passed onto the source protocol A 122 a. The source linklayer 130 then provides a positive ACK 708 to the sink link layer 180 asacknowledgement of a successful communication.

In some embodiments, the phase offsetting of multimedia system 100 andthe retry disparity of multimedia system 500 may be combined into asingle system. In other embodiments, a multimedia system may includeeither the phase offsetting of multimedia system 100 or the retrydisparity of multimedia system 500, but not both.

In one embodiment, a representation of circuitry within the sourcedevice 110 or sink device 115 may be stored as data in a non-transitorycomputer-readable medium (e.g. hard disk drive, flash drive, opticaldrive). These descriptions may be behavioral level, register transferlevel, logic component level, transistor level and layout geometry-leveldescriptions.

Upon reading this disclosure, those of skill in the art will appreciatestill additional alternative designs for a multimedia system for datacommunications over a full duplex control channel of a multimediacommunication link. Thus, while particular embodiments and applicationsof the present disclosure have been illustrated and described, it is tobe understood that the embodiments are not limited to the preciseconstruction and components disclosed herein and that variousmodifications, changes and variations which will be apparent to thoseskilled in the art may be made in the arrangement, operation and detailsof the method and apparatus of the present disclosure disclosed hereinwithout departing from the spirit and scope of the disclosure as definedin the appended claims.

What is claimed is:
 1. A system for data communications, the systemcomprising: a multimedia communication link having a full duplex controlchannel; a source device to communicate data over the full duplexcontrol channel of the multimedia communication link, the source devicehaving a first link layer that retries unsuccessful data communicationsover the full duplex control channel until a first maximum retry limitof the first link layer is reached; and a sink device to communicatedata over the full duplex control channel of the multimediacommunication link, the sink device having a second link layer thatretries unsuccessful data communications over the full duplex controlchannel until a second maximum retry limit of the second link layer isreached, the second maximum retry limit being different than the firstmaximum retry limit.
 2. The system of claim 1, wherein the first maximumretry limit is higher than the second maximum retry limit.
 3. The systemof claim 1, wherein the first maximum retry limit is lower than thesecond maximum retry limit.
 4. The system of claim 1, wherein the firstmaximum retry limit is equal to 4X+3, wherein X is an integer.
 5. Thesystem of claim 4, wherein the second maximum retry limit is equal to4Y+1, wherein Y is an integer.
 6. The system of claim 1, wherein anunsuccessful data communication is indicated by a receipt of a negativeacknowledgement via the full duplex control channel.
 7. The system ofclaim 1, wherein the data communicated by the source device correspondsto data from a half-duplex translation layer protocol.
 8. A first devicefor data communications with a second device via a multimediacommunication link, the first device comprising: an interface to a fullduplex control channel of the multimedia communication link; and a linklayer to communicate data with the second device over the full duplexcontrol channel, the link layer to retry unsuccessful datacommunications over the full duplex control channel until a firstmaximum retry limit is reached, the first maximum retry limit beingdifferent than a second maximum retry limit of a link layer of thesecond device.
 9. The first device of claim 8, wherein the first maximumretry limit is higher than the second maximum retry limit.
 10. The firstdevice of claim 8, wherein the first maximum retry limit is lower thanthe second maximum retry limit.
 11. The first device of claim 8, whereinthe first maximum retry limit is equal to 4X+3, wherein X is an integer.12. The first device of claim 11, wherein the second maximum retry limitis equal to 4Y+1, wherein Y is an integer.
 13. The first device of claim8, wherein an unsuccessful communication is indicated by a receipt of anegative acknowledgement via the full duplex control channel.
 14. Thefirst device of claim 8, wherein the data communicated by the firstdevice corresponds to data from a half-duplex translation layerprotocol.
 15. A non-transitory computer readable medium storing arepresentation of a first device for data communications with a seconddevice via a multimedia communication link, the first device comprising:an interface to a full duplex control channel of the multimediacommunication link; and a link layer to communicate data with the seconddevice over the full duplex control channel, the link layer to retryunsuccessful data communications over the full duplex control channeluntil a first maximum retry limit is reached, the first maximum retrylimit being different than a second maximum retry limit of a link layerof the second device.
 16. The non-transitory computer readable medium ofclaim 15, wherein the first maximum retry limit is higher than thesecond maximum retry limit.
 17. The non-transitory computer readablemedium of claim 15, wherein the first maximum retry limit is lower thanthe second maximum retry limit.
 18. The non-transitory computer readablemedium of claim 15, wherein the first maximum retry limit is equal to4X+3, wherein X is an integer.
 19. The non-transitory computer readablemedium of claim 18, wherein the second maximum retry limit is equal to4Y+1, wherein Y is an integer.
 20. The non-transitory computer readablemedium of claim 15, wherein an unsuccessful communication is indicatedby a receipt of a negative acknowledgement via the full duplex controlchannel.